Communication pubs.acs.org/IC
Binding of EuIII to 1,2-Hydroxypyridinone-Modified Peptide Nucleic Acids Arnie R. de Leon,† Abiola O. Olatunde,‡ Janet R. Morrow,*,‡ and Catalina Achim*,† †
Department of Chemistry, Carnegie Mellon University, 4400 Fifth Avenue, Pittsburgh, Pennsylvania 15213, United States Department of Chemistry, University at Buffalo, State University of New York, Amherst, New York 14260, United States
‡
S Supporting Information *
have incorporated this ligand into a PNA monomer and used the monomer to create a binding site for EuIII in a PNA duplex. The 1,2-HOPOBn acid was synthesized according to a slightly modified procedure4 and was coupled to Boc-protected tertbutylaminoethyl glycinate to obtain the tert-butyl ester of the PNA-HOPO monomer,5 which was hydrolyzed using NaOH (Schemes 1 and S1 in the Supporting Information, SI). The
ABSTRACT: Substitution of a nucleobase pair with a pair of 1,2-hydroxypyridinone (1,2-HOPO) ligands in the center of a 10-base-pair peptide nucleic acid (PNA) duplex provides a strong binding site for EuIII as evidenced by UV thermal melting curves, UV titrations, and luminescence spectroscopy. EuIII excitation spectra and luminescence lifetime data are consistent with EuIII bound to both 1,2 HOPO ligands in a PNA-HOPO duplex as the major species present in solution.
Scheme 1
T
he self-assembly and molecular recognition properties of nucleic acids and of their synthetic analogues, such as peptide nucleic acids (PNAs), facilitate the design of new functional supramolecular structures that have applications as sensors for small molecules or nanomachines for molecular computing or drug delivery. Inorganic chemists have been at the forefront of this research by capitalizing on the interesting spectroscopic, redox, and magnetic properties of metal ions. These ions have been incorporated in both nonmodified and modified nucleic acids to form hybrid inorganic−nucleic acid molecules. A strategy for the incorporation of metal ions into nucleic acids is to use ligand-modified nucleic acid monomers instead of nucleobases.1 PNAs are uniquely suited for the incorporation of ligands for binding of metal ions because the ligands can be readily connected to the PNA backbone through a peptide linker. Nucleobase-like ligands such as bipyridine or 8hydroxyquinoline have been incorporated pairwise into the two strands of PNA duplexes.1b Most studies of metal-containing, ligand-modified nucleic acids have involved transition-metal ions that form four-coordinate complexes (it is possible that the metal weakly coordinates two more ligands, e.g., nucleobases, to achieve six-coordination). To the best of our knowledge, large metal ions such as trivalent lanthanides have not been incorporated into metal complexes within PNA, although a DNA with a non-nucleoside linker was shown to bind EuIII in a bulgelike structure.2 Here we report the first example of a lanthanide ion incorporated into PNA by the substitution of nucleobases with bidentate ligands. The rich luminescence, magnetic, and catalytic properties of the lanthanide ions together with the specific and high affinity binding of PNA to DNA and RNA make compounds such as the one we report here interesting for the design of new classes of optical and MRI sensors. 1,2-Hydroxypyridinone (1,2-HOPO) is a ligand with a high affinity for lanthanides and can sensitize EuIII luminescence.3 We © 2012 American Chemical Society
PNA-HOPO monomer was incorporated into two complementary PNA oligomers with the sequence shown in Scheme 1 by solid-phase peptide synthesis.6 The bidentate ligand Pr-1,2HOPO (Scheme 1) was also synthesized (Scheme S2 in the SI).7 To improve the PNA solubility, we included at the C end of each oligomer one or three lysine residues (Lys PNA-HOPO or Lys3 PNA-HOPO, respectively). The solubility, melting, and optical properties of the PNA duplexes with different numbers of lysines are similar. Variable-temperature UV−vis spectroscopy was used to evaluate the thermal stability of the nonmodified and HOPOcontaining PNA duplexes (Figure 1). The UV melting curves showed that the Lys3 PNA-HOPO duplex has a Tm of ∼47 °C, which is 21 °C lower than the Tm of the nonmodified PNA duplex and is comparable to that of PNA duplexes with the same sequence that had a central pair of bipyridine ligands.8 The melting temperature of either of the two PNA-HOPO duplexes measured in the presence of EuIII was higher by several degrees than that measured in the absence of EuIII (Table 1), which suggests that the EuIII−1,2-HOPO coordination bonds contribute to the duplex stability. This suggestion is supported by the Received: August 15, 2012 Published: November 13, 2012 12597
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Communication
of the nucleobases is also observed. This decrease is indicative of changes in the nucleobase stacking caused by EuIII interaction with 1,2-HOPO (Figure 2). An increase in the absorbance at 312 nm as a function of the EuIII/Lys3 PNA-HOPO ratio can be fitted to the formation of EuIII complexes with two to four 1,2HOPO ligands from Lys3 PNA-HOPO duplexes (see below). The circular dichroism (CD) spectrum of the Lys PNAHOPO duplex is consistent with the presence in solution of a left-handed duplex; the preferred handedness is induced by L-Lys at the C end of the PNA oligomers (Figure S4 in the SI).9 The CD amplitude decreased in the presence of EuIII. Considered together with the cooperative melting curve for the Lys PNAHOPO duplex in the presence of EuIII, this observation indicates a decrease in the chiral induction effect exerted by L-Lys in the EuIII-containing PNA, and it suggests that EuIII coordination to the 1,2-HOPO ligands in the Lys PNA-HOPO duplex causes structural changes in the duplex. Luminescence spectroscopy experiments support binding of EuIII to the 1,2-HOPO ligands of the Lys PNA-HOPO duplex. Excitation at λ = 318 nm of the HOPO moiety of Lys PNAHOPO in solutions that contain 1 equiv of EuIII (with respect to the duplex) gives rise to a typical EuIII emission spectrum that has a pronounced 5D0 → 7F2 emission peak at 614 nm (Figure S5 in the SI). These spectral data show that 1,2-HOPO sensitizes EuIII luminescence through the formation of a coordination complex. More information is obtained from direct excitation spectroscopy of the 7F0 → 5D0 transition of EuIII in which luminescence is monitored at the 5D0 → 7F2 emission through a bandpass filter (628 ± 27 nm). The excitation spectra of a solution containing EuIII at varying concentrations of the Lys PNA-HOPO duplex are shown in Figures 3 and S6 in the SI. A peak-fitting analysis of
Figure 1. UV melting curves measured at 260 nm for 5 μM Lys3 PNAHOPO duplex (black) and a nonmodified PNA duplex (red) in the absence (solid line) and presence of 0.50 equiv (dotted line) and 1.0 equiv (dashed line) of EuIII per duplex in pH 6.5, 20 mM MES, and 0.10 M NaCl buffer.
Table 1. Melting Temperature of PNA (Tm/°C) in the Absence and Presence of EuIII EuIII/ds PNA 0 0.5 1.0
ds PNA 68 68 68
ds Lys HOPO 48 52 52
ds Lys3 HOPO 47 52 54
fact that the thermal melting temperatures of nonmodified PNA in the absence and presence of 1 equiv of EuIII are the same (Figure 1). UV titration of Lys3 PNA-HOPO with EuIII is consistent with EuIII coordination to the 1,2-HOPO ligands (Figures 2 and S2 in
Figure 3. (a) 7F0→ 5D0 excitation spectrum of a 20 μM EuIII solution in pH 6.50, 0.020 M MES, and 0.100 M NaCl buffer (λem = 628 ± 27 nm) in the presence of an increasing amount of Lys PNA-HOPO from 3.18 μM to 53.4 μM. Top of the inset: excitation spectrum of the solution containing 42.2 μM Lys PNA-HOPO and 20 μM EuIII, 0.10 M NaCl, and 0.020 M MES at pH 6.5. Bottom of the inset: peak-fit analysis of the spectrum showing two bands at 579.21 and 579.72 nm.
Figure 2. (a) UV titration spectra for a 10 μM solution of the Lys3 PNA HOPO duplex in pH 6.5, 20 mM MES, 0.10 M NaCl buffer with EuIII, measured 10 min after each addition of EuIII. The final concentration of EuIII was 15 μM. Each addition was of 4 μL of a 100 μM solution of EuIII solution. The inset shows an expanded view of the spectra. (b) Fit of the absorbance at 312 nm as a function of the volume of EuIII to a binding isotherm using the equilibria listed in Table S4 in the SI.
the excitation spectrum at either a 1:1 or 1:2 ratio of EuIII/Lys PNA-HOPO duplex shows two major peaks centered at 579.21 and 579.72 nm (Figure 3). For comparison, solutions containing Pr-1,2-HOPO4b and EuIII in a 1:4 ratio give excitation spectra with peaks at 579.53 and 579.90 nm (Figures S7 and S8 in the SI). The red-shifted excitation peaks for EuIII bound to Lys PNAHOPO or Pr-1,2-HOPO are consistent with the addition of an anionic donor group to the EuIII coordination.10 In contrast, titration of nonmodified PNA with EuIII leads to a slight
the SI). Upon the addition of EuIII, the UV spectrum of the duplex shows changes in the absorption at 290−400 nm, which corresponds to n−π* transitions of HOPO (Figure 2). In contrast, titration of EuIII into a solution of nonmodified PNA gives rise to a very small decrease in absorbance at 260 nm (Figure S3 in the SI). These spectral changes are indicative of the coordination of EuIII to the 1,2-HOPO ligands of the Lys3 PNAHOPO duplex. A decrease in the absorbance of the 260 nm band 12598
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quenching of the free EuIII excitation peak but no further shift of the excitation peaks (Figure S9 in the SI). Luminescence lifetime data give further information about the EuIII species in solution. Excitation at several wavelengths across the excitation peak in solutions containing either 1:1 or 1:2 EuIII/ Lys PNA-HOPO at 20 μM EuIII gives luminescence lifetimes consistent with 4 or 5 bound water molecules (q number), respectively (Table S1 and eq S1 in the SI). This is consistent with the displacement of four out of nine water ligands of EuIII upon binding to two 1,2-HOPO moieties in a single Lys PNAHOPO duplex. That similar luminescence lifetimes are recorded suggests that the two peaks represent two different isomers of EuIII bound to Lys PNA-HOPO with the same number of bound water molecules. Alternately, interconversion of two species each with different numbers of water ligands that is rapid on the luminescence lifetime time scale may give rise to an average q number. Solutions with EuIII and nonmodified PNA under similar conditions contain fully hydrated EuIII (Table S2 in the SI). For solutions containing Pr-1,2-HOPO and EuIII in a 1:1 ratio, luminescence lifetime data are indicative of binding to EuIII of a single bidentate ligand and seven water ligands (q = 7; Table S3 in the SI). Again, the similar lifetimes obtained upon excitation at the two peaks suggest that the two species are isomers with the same number of bound water molecules or, alternatively, are interconverting. Higher ratios of Pr-1,2-HOPO to EuIII (i.e., 4:1) give rise to a third excitation peak and q numbers that are consistent with two bound Pr-1,2-HOPO ligands (Table S3 in the SI). Binding curves derived from both UV−vis titrations and EuIII excitation luminescence spectra as a function of the EuIII or Lys PNA-HOPO concentration, respectively, were used to determine the binding constants of EuIII complexes with the PNAHOPO duplexes (Figures S10 and S11 in the SI). The unusual shape of the binding curve at the three excitation wavelengths suggests the coexistence in solution of more than one EuIII species. Fitting of the data using HyperSpec required three species including Eu2L, EuL, and EuL2, where L is a Lys PNA-HOPO duplex. The majority species under most conditions (10−20 μM EuIII and 1−2 equiv of the Lys PNA-HOPO duplex) is the 1:1 EuL complex. However, when the Lys PNA-HOPO duplex is in excess, the data are consistent with the formation of a EuL2 species, presumably involving two Lys PNA-HOPO duplexes binding to one EuIII. Conversely, at excess EuIII to Lys PNAHOPO, Eu2L is formed. Detailed information about the coordination sphere of EuIII in Eu2L or EuL2 is difficult to obtain because these species are not present in solution in sufficiently large concentrations to distinguish their spectroscopic signatures from those of the EuL complex. The binding constants for these EuL2, EuL, EuL2 species are given in Table S4 in the SI. Of these constants, the most important is that for the EuL complex, log K = 9.4. By comparison, titration of Pr-1,2-HOPO with EuIII (Figure S12 in the SI) gave a binding isotherm that was fit to the formation of mono-, di-, and triadducts of EuIII with the ligand. The binding constant for Eu(Pr-1,2-HOPO)2, log β = 5.4, is 4 orders of magnitude weaker than that for the complex formed between EuIII and the Lys PNA-HOPO duplex. We attribute this difference in the binding constants to a supramolecular chelate effect exerted by the duplex on the complex of EuIII with 1,2HOPO. This effect was previously observed for complexes formed by CuII with PNA duplexes containing 8-hydroxyquinoline as well as for metal complexes within ligand-modified ds DNA.1b,11
The results of this study establish that it is possible to coordinate EuIII to PNA duplexes modified with ligands for lanthanides. Our data suggest that EuIII can bind to both HOPO moieties of the duplex and retains five coordinated water molecules. This approach leads to PNA duplexes with binding sites for EuIII that retain bound waters required for MRI applications.
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ASSOCIATED CONTENT
S Supporting Information *
The synthesis of the HOPO-modified PNA monomer, Pr-1,2HOPO, and PNA oligomers, excitation spectra and simulations, melting curves and UV spectra of the Lys PNA-HOPO duplex, luminescence lifetimes and q numbers for EuIII complexes with Pr-1,2-HOPO and Lys PNA-HOPO. This material is available free of charge via the Internet at http://pubs.acs.org.
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AUTHOR INFORMATION
Corresponding Author
*E-mail: jmorrow@buffalo.edu (J.R.M.),
[email protected] (C.A.). Notes
The authors declare no competing financial interest.
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ACKNOWLEDGMENTS We thank the NSF for support of the work (Grant CHE-0848725 to C.A., Grants CHE-9808188, DBI-9729351, and CHE0130903 for partial support of the mass spectrometry and NMR instruments at Carnegie Mellon, Grant CHE-0911375 to J.R.M., and Grant CHE-0321058 to J.R.M. to build the laser system).
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